Source 1primary paper2001The Plant Cell
Toolkit/expressed sequence tag-based microarray
expressed sequence tag-based microarray
Taxonomy: Technique Branch / Method. Workflows sit above the mechanism and technique branches rather than replacing them.
Summary
An expressed sequence tag-based microarray is a microarray expression-profiling assay used to measure genome-scale transcript patterns in Arabidopsis. In the cited study, it was applied to profile gene expression underlying light-controlled development across different light conditions.
Usefulness & Problems
Why this is useful
This assay is useful for surveying coordinated changes in transcript abundance across many genes during plant developmental responses to light. The cited work used it to connect light-regulated Arabidopsis development with genome-wide expression changes in metabolic and regulatory pathways.
Problem solved
It addresses the problem of measuring genome-scale transcriptional responses associated with light control of Arabidopsis development. In the cited study, it enabled comparison of expression patterns under far-red, red, and blue light conditions.
Problem links
Need precise spatiotemporal control with light input
DerivedAn expressed sequence tag-based microarray is a gene expression profiling assay used to measure genome-scale transcript patterns in Arabidopsis during light-regulated development. In the cited study, it was applied to characterize expression changes associated with far-red, red, blue, and light/dark transition conditions.
Taxonomy & Function
Primary hierarchy
Technique Branch
Method: A concrete measurement method used to characterize an engineered system.
Mechanisms
nucleic acid hybridizationnucleic acid hybridizationtranscript abundance measurementtranscript abundance measurementTechniques
Functional AssayTarget processes
No target processes tagged yet.
Input: Light
Implementation Constraints
cofactor dependency: cofactor requirement unknownencoding mode: genetically encodedimplementation constraint: context specific validationimplementation constraint: spectral hardware requirementoperating role: sensor
The available evidence indicates an expressed sequence tag-based microarray format and application to Arabidopsis seedlings exposed to light conditions including far-red, red, and blue light. Specific array composition, labeling chemistry, hybridization conditions, normalization methods, and sample preparation details are not provided in the supplied evidence.
The supplied evidence only establishes use for Arabidopsis light-response profiling and does not provide performance metrics such as sensitivity, dynamic range, reproducibility, or probe coverage. Independent replication, cross-platform validation, and implementation details are not described in the provided evidence.
Validation
Cell-freeBacteriaMammalianMouseHumanTherapeuticIndep. Replication
Supporting Sources
Ranked Claims
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
fraction of genome similarly regulated approximately one-third
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
coordinately regulated cellular pathways 26
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
downregulated fraction two-fifthsupregulated fraction three-fifths
Approval Evidence
1 source7 linked approval claimsfirst-pass slug expressed-sequence-tag-based-microarray
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
Source:
developmental mechanismsupports
Light controls Arabidopsis development through coordinated regulation of metabolic and regulatory pathways.
Thus, light controls Arabidopsis development through coordinately regulating metabolic and regulatory pathways.
Source:
gene expression patternsupports
Light/dark transitions triggered similar differential genome expression profiles.
Furthermore, light/dark transitions also triggered similar differential genome expression profiles.
Source:
gene expression patternsupports
Seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles.
Qualitatively similar gene expression profiles were observed among seedlings grown in different light qualities, including far-red, red, and blue light, which are mediated primarily by phytochrome A, phytochrome B, and the cryptochromes, respectively.
Source:
genome fraction estimatesupports
Similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome.
The similarly regulated genes in all light conditions were estimated to account for approximately one-third of the genome
Source:
method usesupports
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
An expressed sequence tag-based microarray was used to profile genome expression underlying light control of Arabidopsis development.
Source:
pathway regulationsupports
Analysis of light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Analysis of those light-regulated genes revealed more than 26 cellular pathways that are regulated coordinately by light.
Source:
regulation direction distributionsupports
Among similarly regulated genes in all light conditions, three-fifths were upregulated and two-fifths were downregulated by light.
with three-fifths upregulated and two-fifths downregulated by light
Source:
Comparisons
Source-backed strengths
The assay supported genome-expression profiling at broad scale in Arabidopsis seedlings during light-regulated development. The cited study reported that seedlings grown in far-red, red, and blue light showed qualitatively similar gene expression profiles, indicating utility for comparative condition-dependent transcript analysis.
Compared with Affymetrix ATH1 microarray
expressed sequence tag-based microarray and Affymetrix ATH1 microarray address a similar problem space.
Shared frame: same top-level item type; shared mechanisms: nucleic acid hybridization, transcript abundance measurement; same primary input modality: light
Compared with cDNA microarray
expressed sequence tag-based microarray and cDNA microarray address a similar problem space.
Shared frame: same top-level item type; shared mechanisms: nucleic acid hybridization; same primary input modality: light
Compared with native green gel system
expressed sequence tag-based microarray and native green gel system address a similar problem space.
Shared frame: same top-level item type; same primary input modality: light
Ranked Citations
- 1.